EPOXI/EPOCh Observations of Transiting Extrasolar Planets Drake Deming February 20, 2009 Use or disclosure of information contained on this sheet is subject to the restriction on the title page of this presentation.
What I m Going to Discuss... Science value of transiting planets History of EPOXI - why the funny name Quality of our data, and what we will learn Earth-as-an-extrasolar-planet
Since 1995, more than 300 extrasolar planets have been discovered - most by radial velocity (indirect detection) G. Laughlin & J. Cho Many of these planets are close to their stars (0.05 AU) - the hot Jupiters
Close-in planets have a high probability to transit Transiting Planets Discovery Rate Number 16 14 12 10 8 6 4 2 0 2000 2002 2004 2006 2008 Year All V < 13 36 exoplanets are now known transiting bright solar-type stars & discovery rate is accelerating
Transit Science
Mass & Radius from transits inform us of the planet s average interior structure
History of EPOXI Deep Impact Prime mission impacted Comet Tempel-2 in July 2005, then the flyby spacecraft entered a storage orbit 2006 Discovery AO, solicited re-use as Mission-of-Opporunity. Selections included: Extrasolar Planet Observations and Characterization (EPOCh, D. Deming et al.) - Use the CCD imager to acquire high-precision transit photometry - Known, bright, transiting systems (follow-up, not discovery) Deep Impact extended Investigation (DIXI, M. A Hearn et al.) Selection Letters dictated a combined investigation for Step-2 EPOCh + DIXI = EPOXI...voila! EPOXI was confirmed for Step-2 in October 2007 Nice acronym... - Alan Stern
EPOCh Science Team Drake Deming (GSFC), Principal Investigator David Charbonneau (Harvard), Deputy P.I. Sarah Ballard (CfA) Richard Barry (GSFC) Nick Cowan (Univ. Wash) Jessie Christiansen (CfA) Don Hampton (U. Alaska) Tilak Hewagama (U. MD) Matt Holman (SAO) Marc Kuchner (GSFC) Carey Lisse (APL) Timothy Livengood (NCESSE) Vikki Meadows (U. Wash.) Tyler Robinson (U. Wash) Alfred Schultz (GSFC) Sara Seager (MIT) Joseph Veverka (Cornell) Dennis Wellnitz (U. MD)
Spacecraft pointing (in)stability is our principal challenge
Why we need spaceborne data... For higher S/N photometry improved radii for the giant planets reflected light - or thermal emission rings and moons detection of even smaller planets transit timing to ~ seconds precision Continuous coverage discovery of smaller planets Trojan planets? EPOCh transit of a Neptune-sized planet in GJ 436 Capitalize the defocus...!
Our targets... observed Jan-Aug, 2008 EPOXI in follow-up mode, unlike Kepler HAT-P-4 a puffed up giant planet, R~1.3 times Jupiter, M~0.7 times Jupiter TrES-3 a giant planet in a 31-hour orbit! potential for large reflected light signal (0.1%)! WASP-3 a strongly heated giant planet - thermal emission in the visible? TrES-2 a giant planet in the Kepler field... can combine with Kepler data HAT-P-7 even more strongly heated than WASP-3; also in Kepler field GJ 436 Smallest known transiting planet (Neptune-sized); M-dwarf star Super-earths are predicted! We covered out to the habitable zone!
Family portrait 1.2 Re limit at 4-sigma
Nearly photon-limited precision...
Search for an Earth-sized planet (in GJ436) Eccentric orbit requires perturbation by a second planet... so the theorists say If the second planet lies in the same plane, it should transit also... EPOXI observed the system for 22 days...
Results of our search... Results show that no other planets transit, down to about 1.5 Earth radii...how is e for GJ436b maintained?
EPOCh Earth Observations Imaging in all HRI filters hourly, (some at 15 min cadence) IR spectroscopy twice hourly Study the Earth-as-an-exoplanet: rotational light curves inversion mapping calibrated astronomical colors model-independent spectroscopy validation of the VPL
IR-green-blue vs. Red-green-blue let me be very clear: the following is just about the coolest thing I have ever seen - Phil Plait Image deconvolutions by Don Lindler (GSFC) IR-green-blue (still frame) Red-green-blue (still frame)
Inversion Mapping of Earth Sum the EPOXI data spatially - Earth as single pixel Use PCA to infer what spectral components are present...then invert the time history of those components as the Earth rotates
Alien Maps of an Ocean-Bearing World Inversion maps show oceans and continents, but with no latitude resolution TPF will be able to infer the presence of oceans on Earth-like exoplanets